KR20160136783A - Dielectric Resonator - Google Patents

Abstract

Provided is a dielectric resonator comprising: a housing having one open side and an accommodation space inside; a cover to cover the open side of the housing; a metal plate fixated on the bottom surface of the housing; a dielectric resonance device fixated on the metal plate and accommodated inside the accommodation space of the housing; and a metallic conductive elastic gasket disposed between the dielectric resonance device and the cover. The dielectric resonator of the present invention has stable characteristics due to the stable structure even if there is a temperature variation and realizes an excellent Q factor. Moreover, the dielectric resonator of the present invention is able to be manufactured with low costs since the assembly is easy due to its simple structure.

Description

Dielectric Resonator

The present invention relates to a dielectric resonator, and more particularly, to a dielectric resonator of a high-frequency filter exhibiting stable characteristics with respect to temperature changes.

High-frequency filters (DR filter, cavity filter, waveguide filter, etc.) have a structure of a kind of circuit box for resonating high frequency, especially very high frequency. Generally, a resonant circuit by a coil and a capacitor is not suitable for forming a very high frequency because of a large radiation loss. The RF filter is composed of a plurality of resonators. Each resonator forms a cavity such as a metallic cylinder or a rectangular parallelepiped surrounded by a conductor and includes a resonance element formed of a dielectric resonance element (DR) or a metal resonance element in the cavity, So that resonance of a very high frequency can be realized.

The RF filter can be classified into a TM (Transverse Magnetic) mode, a TEM (Transverse Electro Magnetic) mode and a TE (Transverse Electric) mode according to the structure of the resonator. As a technique for a TM mode resonator, a method disclosed in U.S. Patent No. 7,106,152 (name: DIELECTRIC RESONATOR, DIELECTRIC FILTER, AND METHOD OF SUPPORTING DIELECTRIC RESONANCE ELEMENT, inventor: Takehiko Yamakawa et al., Patent date: September 12, 2006) .

Since the TM mode resonator has a higher Q value than the conventional TEM mode resonator (cavity filter structure), it shows an improved Q characteristic of about 40% at the same size. Due to these characteristics, the TM mode resonator filter can be designed in a very small size as compared with the TEM mode resonator filter, and a filter having a small insertion loss and an excellent attenuation characteristic can be designed at the same size.

Of course, the TE01 δ mode resonator filter, which uses a similar dielectric resonator, has a Q value as high as three times higher than that of the TEM mode resonator, but its manufacturing cost is several times higher and a very large volume is required. . Therefore, it is a resonator that can not be applied to small-sized products.

1, the TM mode resonator has a rod-shaped dielectric resonator element 5 at the center of a space formed by the metal cover 3 and the housing 4 The dielectric resonator element 5 is assembled such that both end faces of the dielectric resonator element 5 are closely contacted with the upper and lower surfaces of the inside of the accommodation space. A tuning groove may be formed at the upper end of the dielectric resonator element 5 and a tuning screw 1 for tuning the frequency may be installed in the cover 3 at a position corresponding to the tuning groove with a fixing nut 2.

In this structure, it is very important that both end faces of the dielectric resonator element 5 are assembled in close contact with the upper and lower surfaces inside the accommodation space. If this portion is unstable, the characteristics of the dielectric resonance element 5 vary greatly depending on temperature changes.

In order to solve this problem, generally, as shown in FIG. 2, metalizing 6 is formed on both end surfaces of the dielectric resonator element 5, and then the housing 4 and the cover 3 are formed by soldering, Or assembled by other methods.

In this case, due to the machining tolerance of the dielectric resonant element and the machining tolerance of the housing, the same force is applied to all the dielectric resonant elements constituting the RF filter to assemble the metal plate So that it is difficult to fabricate a stable structure. In particular, since the thermal expansion coefficient of the dielectric resonance element is different from that of the housing, the dielectric resonance element is deteriorated in the fixed state or the contact state due to the expansion and contraction due to the temperature change.

Patent Registration No. 10-1072284 (registered on October 10, 2011) proposes a structure of a dielectric resonator of a high-frequency filter for solving the above problems. In the proposed dielectric resonator structure, a guide groove and an air gap groove are formed on the bottom surface of the housing to stably bring the dielectric resonator element into contact with the bottom surface of the housing. Also, a metal plate is sandwiched between the cover and the dielectric resonator element, It is possible to fabricate a resonator without having to perform a soldering process by fixing the dielectric resonance element by sandwiching the dielectric resonance element at the center of the lid. Thus, the work process is easy, and a stable structure can be formed.

Patent Registration No. 10-0737618 (registered on Mar. 07, 03, 2007) discloses a dielectric resonator of a high frequency filter in which a dielectric body is housed in a box body and a lid, in which a conductor foil and an elastic body layer are interposed between the dielectric body and the lid Of the dielectric resonator.

Patent Registration No. 10-1208165 (registered on November 28, 2012) discloses a dielectric resonator filter having a stable ground structure. The proposed dielectric resonator filter has a structure in which a cover having elasticity is provided in a state where the height of the dielectric resonator is higher than the height of the housing, so that a stable grounding structure can be maintained.

Patent Registration No. 10-1307107 (Registered on Mar. 09, 04, 2013) discloses a dielectric resonator filter in which a dielectric resonator is accommodated in an inner space of a housing and a cover, an end of a cover is formed, Discloses a dielectric resonator filter in which a cover stably contacts a dielectric resonator by fastening a coupling bolt threaded into such a thread.

Patent Registration No. 10-1479152 (Registered on Dec. 29, 2014) discloses a transverse mode dielectric resonator suitable for mass production because of its excellent structural stability, convenient assembling, and high feasibility. The disclosed dielectric resonator comprises a thin cover plate and a thick cover plate, wherein a slot is formed in the surface of the thick cover plate and the slot is filled with an elastically deformable filler so that the contact between the contact surfaces It is excellent and makes assembly simple.

According to the above-mentioned prior art, although the contact and assemblability between the housing and the cover and the dielectric resonator element are improved in the dielectric resonator, particularly the TM mode dielectric resonator, there is still room for improvement.

Accordingly, it is an object of the present invention to provide a dielectric resonator, particularly a TM mode dielectric resonator, which exhibits stable characteristics with respect to temperature changes and also has a high Q value and is structurally stable.

According to an aspect of the present invention, there is provided a dielectric resonator comprising: a housing having one side opened and a receiving space therein; A cover covering an opening of the housing; A metal plate fixed to a bottom surface of the housing; A dielectric resonator element fixedly mounted on the metal plate and received in the housing space of the housing; And a conductive elastic gasket interposed between the dielectric and the lid and made of a metal material. The dielectric resonator of the present invention is a TM mode dielectric resonator in particular.

It is preferable that the dielectric resonator element has a cylindrical or polygonal cylinder shape having a through-hole hollow in the center.

The metal plate may include a central protruding portion formed in the upper portion of the circular or polygonal dielectric resonator element seating plate on which the dielectric resonator element is mounted and the central portion of the upper portion of the dielectric resonator element plate and sandwiching the through-hole hollow of the dielectric resonator element desirable.

A rim protrusion is formed on a rim portion of the metal plate, and a region between the rim protruding portion and the center rim portion is formed by fitting a dielectric resonator element to the dielectric resonator element, It is preferable that the grooves are formed.

It is preferable that the metal plate has a structure in which the metal plate is in close contact with the bottom surface of the housing at the periphery of the bottom surface but is not in close contact with the bottom surface of the housing at the center of the bottom surface, .

Wherein the upper surface of the resonator element plate of the metal plate and the central protrusion portion are provided with screw through holes through which screws are passed in order and a screw through hole is also formed in the bottom surface of the housing, And the metal plate is fixed to the bottom surface of the housing by screwing the through hole.

Preferably, the dielectric resonator element and the metal plate are further coupled by soldering.

The conductive elastic gasket has a structure in which an upper surface thereof is an open shape except for a circular or polygonal edge portion that contacts the lid. The lower surface of the conductive elastic gasket has protrusions formed on a circular or polygonal rim, It is preferable that the inner region of the protrusion is formed by the dielectric resonator element mounting groove, and the side surface is formed in a structure having a wide upper portion and a narrower lower portion.

Preferably, the conductive elastic gasket further includes an extended portion extending from the circular or polygonal rim portion in contact with the lid and extending horizontally or inclined downwardly.

The conductive elastic gasket may be made of an alloy of beryllium and copper.

Wherein the lid includes an outer lid and an inner lid, the outer lid has a rim portion covering the rim of the opening of the housing, and an inner lid seating groove portion in which the inner lid is seated is formed in the rim portion, A center hole for allowing the conductive elastic gasket to pass therethrough is formed at the center of the inner lid seating groove, and the inner lid may be engaged with the inner lid seating groove of the outer lid.

According to an aspect of the present invention, there is provided a dielectric resonator comprising: a housing having one side opened and a dielectric resonator element insertion protrusion formed on a bottom surface thereof and having a receiving space therein; A cover covering an opening of the housing; A lower conductive elastic gasket formed of a metal material and fitted to the dielectric resonator element fitting protrusion formed on the bottom surface of the housing and closely contacting the bottom surface of the housing; The housing having a cylindrical or polygonal cylindrical shape having a through hole in the center thereof and being fitted in the dielectric resonator element fitting protrusion formed on the bottom surface of the housing and fixed on the lower conductive elastic gasket, A dielectric resonator element; And a top conductive elastic gasket interposed between the dielectric and the lid and made of a metal material.

The upper conductive elastic gasket has a structure in which an upper surface thereof is formed in an open shape except for a circular or polygonal rim portion which contacts the lid and a lower surface is a place where the dielectric resonator element is seated and protrusions are formed on a circular or polygonal rim portion, The lower conductive elastic gasket has a bottom surface and a bottom surface. The lower conductive elastic gasket has an inner area formed by the dielectric resonator element mounting groove, And the upper surface has a through hole through which a dielectric resonator element fitting protrusion provided on the bottom surface of the housing passes, and the upper surface is also in contact with the dielectric resonator element, Round or multiple It is preferable that the inside region of the protrusion protruded by the protrusion is formed as a dielectric resonator element mounting groove and the side face is narrow and the bottom portion is inclined.

Wherein the upper conductive elastic gasket further comprises an extended portion extending from a circular or polygonal rim portion in contact with the lid and extending horizontally or inclined downward, wherein a lower surface of the lower conductive elastic gasket is in contact with a bottom surface of the housing, It is preferable that an extended portion extending horizontally or inclining downward is further provided from the circular or polygonal frame portion.

The upper and lower conductive elastic gaskets may be made of an alloy of beryllium and copper.

Wherein the lid includes an outer lid and an inner lid, the outer lid has a rim portion covering the rim of the opening of the housing, and an inner lid seating groove portion in which the inner lid is seated is formed in the rim portion, A center hole for allowing the upper conductive elastic gasket to pass through is formed at the center of the inner lid seat recessed portion and the inner lid may be engaged with the inner lid seat recessed portion of the outer lid.

The dielectric resonator of the present invention exhibits stable characteristics due to its stable structure and also realizes excellent Q value. The dielectric resonator of the present invention can also be manufactured at low cost because it is structurally simple and easy to assemble.

1 and 2 are views showing the structure of a conventional dielectric resonator.
3 is a cross-sectional view illustrating a structure of a dielectric resonator according to an embodiment of the present invention.
4 is an exploded perspective view of the dielectric resonator of FIG.
5 is a cross-sectional view illustrating a structure of a dielectric resonator according to another embodiment of the present invention.
6 is an exploded perspective view of the dielectric resonator of FIG.
7 is a cross-sectional view illustrating a structure of a dielectric resonator according to another embodiment of the present invention.
8 is a cross-sectional view illustrating a structure of a dielectric resonator according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

3 and 4, the dielectric resonator 10 of the present invention includes a housing 100, a cover 200, and a dielectric resonator element 300. The housing 100 has one side opened and a housing space inside. The shape of the housing 100 is shown in a rectangular parallelepiped shape in which the inside is hollow and one side is opened. However, the housing 100 may have another shape such as a cylindrical shape. The cover 200 covers the opening face of the housing 100 and has the same shape as the opening face of the housing 100. The dielectric resonator element 300 is accommodated in an inner space formed by the housing 100 and the lid 200 and forms a conductive connection with the bottom surface of the housing 100 and the lid 200. In the present invention, as shown in the figure, the dielectric resonator element 300 is preferably a cylindrical rod shape having a through-hole hollow 310 in the center thereof, but it is also possible to have a polygonal tubular shape.

The dielectric resonator 10 of the present invention is a dielectric resonator 10 in which the dielectric resonator element 300 stably makes conductive contact with the bottom surface of the housing 100 and the lid 200 and this conductive contact remains stable even under temperature changes, A metal plate 400 and a conductive elastic gasket 600 are further included to prevent the dielectric resonator element 300 from being damaged by a progressive external force in accordance with the present invention.

First, the metal plate 400 is fixed to the bottom surface of the housing 100. The dielectric resonator element 300 is fixedly mounted on the metal plate 400.

Specifically, the metal plate 400 includes a dielectric resonator element seating plate upper portion 410 and a central protrusion portion 420. The dielectric resonator element 300 is mounted on the upper portion 410 of the dielectric resonator element plate. The upper part 410 of the dielectric resonator element plate may be formed in a circular or polygonal shape depending on the shape of the dielectric resonator element 300. The center protrusion 420 protrudes from the central portion of the upper portion 410 of the dielectric resonator element, and the through-hole 310 of the dielectric resonator element 300 is inserted.

A rim protrusion 412 is formed at the rim of the upper portion 410 of the dielectric resonator element so that the region between the rim protrusion 412 and the central protrusion 420 protrudes from the dielectric protrusion 412, And is formed as a resonance element mounting groove 414. According to the dielectric resonator element mounting groove 414, the assembled portion of the dielectric resonator element 300 can be protected from the side impact and the dielectric resonator element 300 can be easily positioned when assembled. When the dielectric resonator element 300 is seated and coupled to the dielectric resonator element mounting groove 414, it is preferable that additional coupling by soldering is performed. That is, the coupling between the dielectric resonator element 300 and the metal plate 400 preferably includes additional coupling by soldering. At this time, it is preferable that a conductor film formed by metallization is formed on the bottom surface of the dielectric resonance element. The conductor film can be typically formed by silver (Ag).

On the other hand, the metal plate 400 has a structure in which the metal plate 400 is in close contact with the bottom surface of the housing 100 at the periphery of the bottom surface, but is not in close contact with the bottom surface of the housing 100 at the center of the bottom surface thereof, It is preferable to have the contact groove 416 for the contact portion 416. The metal plate 400 can be easily fixed to the bottom surface of the housing 100 even if the bottom surface of the housing 100 has a poor flatness or rough surface due to the machining tolerance, .

A screw through hole 422 is formed in the upper portion 410 of the resonance element plate and the central protrusion 420 of the metal plate 400 so that the metal plate 400 can be stably fixed to the bottom surface of the housing 100, And a screw through hole 105 is also formed in the bottom surface of the housing 100. [ The metal plate 400 is fixed to the bottom surface of the housing 100 by engaging the metal plate fixing screw 500 with the screw through holes 105 and 422 formed in the bottom surface of the housing 100 and the metal plate 400. [

In the dielectric resonator 10 of the present invention, the housing 100, the cover 200, and the metal plate 400 may be formed of a metal material, particularly aluminum.

Next, the conductive elastic gasket 600 is interposed between the dielectric resonator element 300 and the lid 200. The conductive elastic gasket 600 is made of a metal material, and is particularly preferably made of an alloy of beryllium and copper. The conductive elastic gasket 600 may have a thermal expansion difference due to a change in temperature of the housing 100 and the cover 200 and the dielectric resonator 300 while allowing the dielectric resonator 300 to be electrically coupled to the cover 200. [ So that the conductive coupling between the dielectric resonator element 300 and the lid 200 can be maintained.

To this end, the conductive elastic gasket 600 has a structure in which an upper surface thereof is open, except for a circular or polygonal edge portion 611 which contacts the lid 200. That is, the conductive elastic gasket 600 has no element that can be referred to as an upper surface except for the rim portion 611. However, in the present specification, a virtual upper surface is assumed for convenience of explanation. Preferably, the conductive elastic gasket 600 further includes an extended portion 613 which extends from a circular or polygonal edge portion in contact with the lid 200 and extends horizontally or downwardly. According to the extension portion 613, the contact between the lid 200 and the rim portion 611 is more stably supported.

The conductive elastic gasket 600 has a bottom surface on which the dielectric resonator element 300 is mounted and a protrusion 621 is formed on a circular or polygonal rim portion. And a seating groove 623. The conductive elastic gasket 600 also has a structure in which the side surface 630 has a shape that is wide in the upper part and narrow in the lower part. The shape of the conductive elastic gasket 600 may be circular or polygonal depending on the shape of the dielectric resonator element 300.

When the conductive elastic gasket 600 is coupled with the dielectric resonator element 300, it is preferable that additional bonding by soldering is performed. That is, the coupling between the dielectric resonator element 300 and the conductive elastic gasket 600 preferably includes additional coupling by soldering. At this time, on the upper surface of the dielectric resonator element 300, a conductor film formed by metallization is preferably formed. The conductor film can be typically formed by silver (Ag).

A tuning screw 800 is provided in the hollow 310 of the dielectric resonator element 300 to adjust the resonance frequency. To this end, a tuning screw 800 is inserted into the lid 200 and the conductive elastic gasket 600, The through holes 205 and 625 are formed. The tuning screw 800 is installed to extend from the outside of the lid 200 to the hollow 310 of the dielectric resonator element 300 in order through the lid 200 and the through holes of the conductive elastic gasket 600, A fixing nut 810 is provided to fix the tuning screw 800.

The dielectric resonator 10 of the present invention stably accommodates the dielectric resonator element 300 in the internal space formed by the housing 100 and the lid 200 and the dielectric resonator element 300, So that it is stably fixed by the housing 100 and the lid 200.

In general, since the dielectric resonator element 300 made of ceramics has a large thermal expansion coefficient and the metal such as the housing 100 and the cover 200 has a small thermal expansion coefficient, the housing 100 and the lid 200 are more likely to be expanded and / The dielectric resonator element 300 may be damaged by shrinking and a gap may be formed between the housing 100 or the cover 200 and the dielectric resonator element 300, The dielectric resonator 10 of the present invention solves the above problems due to the difference in thermal expansion coefficient between the housing 100 and the cover 200 and the dielectric resonator 300 by the metal plate 400 and the conductive elastic gasket 600 So that it exhibits stable characteristics even with temperature change and can realize a high Q value. Further, since the dielectric resonator 10 of the present invention is simple in structure, it is easy to assemble.

5 and 6 show a variant embodiment. 5 and 6, only the differences from the above description will be described.

The modified embodiment differs from the above-described embodiment in that the lid 200 is not divided into one but is divided into an outer lid 210 and an inner lid 220, as shown in the figure. Specifically, the outer lid 210 has a rim 212 covering the rim of the open side of the housing 100. An inner cover seat groove 214 on which the inner cover 220 is seated is formed on the inner side of the rim 212. A center hole 216 is formed at the center of the inner lid seat recessed portion 214 to allow the conductive elastic gasket 600 to pass therethrough. The inner lid 220 fits into and engages with the inner lid seating recessed portion 214 of the outer lid 210. The inner lid 220 is fitted into the inner lid seat recessed portion 214 of the outer lid 210 and is securely fixed to the outer lid 210 by being screwed by the screw 700. Needless to say, the inner lid 220 and the outer lid 210 are provided with the screw through holes 218 and 222, respectively.

7 and 8, there is shown a structure according to another aspect of the present invention. The dielectric resonator of the present invention shown in FIGS. 7 and 8 is different from the dielectric resonator described above in that a lower conductive elastic gasket 900 is used in place of the metal plate 400. The other structures are the same, the dielectric resonator of Fig. 7 corresponds to the structure of the dielectric resonator according to Figs. 3 and 4, and the dielectric resonator of Fig. 8 corresponds to the structure of the dielectric resonator according to Fig. 5 and Fig. Therefore, the description of the structure of the corresponding dielectric resonator can be referred to, except for the structure described below.

According to the dielectric resonator 10 of the present invention shown in Figs. 7 and 8, the housing 100 has a dielectric resonator element fitting protrusion 110 on its bottom surface. The hollow 310 of the dielectric resonator element 300 is fitted to the dielectric resonator element fitting protrusion 110 formed on the bottom surface of the housing 100. The lower conductive elastic gasket 900 is inserted into the dielectric resonator element fitting protrusion 110 and is brought into close contact with the bottom surface of the housing 100 before the dielectric resonator element 300 is fitted into the dielectric resonator element fitting protrusion 110 do.

The dielectric resonator element 300 is fixed on the lower conductive elastic gasket 900 when the dielectric resonator element 300 is fitted after the lower conductive elastic gasket 900 is inserted into the dielectric resonator element fitting protrusion 110 .

The specific shape and the coupling structure of the lower conductive elastic gasket 900 are plane symmetrical to the conductive elastic gasket 600 described above (hereinafter referred to as the 'upper conductive elastic gasket' as compared to the lower conductive elastic gasket). The area of the through hole 925 to be fitted in the dielectric resonator element fitting protrusion 110 of the housing 100 in the lower conductive elastic gasket 900 in this surface symmetry is smaller than the area of the tuning screw 800 in the upper conductive elastic gasket 600. [ It is not necessarily required to match the area of the through hole 625 to be fitted. In this regard, the bottom conductive elastomeric gasket 900 may not be plane symmetric with the top conductive elastomeric gasket 600. Here, the reference symmetry plane is a plane perpendicular to the longitudinal direction of the dielectric resonator element 300, passing through the center of the dielectric resonator element 300.

The lower conductive elastic gasket 900 is interposed between the dielectric resonator element 300 and the bottom surface of the housing 100. [ Like the upper conductive elastic gasket 600, the lower conductive elastic gasket 900 is made of a metal material, and is preferably made of an alloy of beryllium and copper. The lower conductive elastic gasket 900 is configured to allow the dielectric resonator element 300 to establish a conductive coupling with the bottom surface of the housing 100 while changing the temperature of the housing 100 and the cover 200 and the dielectric resonator element 300 The gap between the dielectric resonator 300 and the bottom surface of the housing 100 can be maintained.

For this, the lower conductive elastic gasket 900 has a structure in which the lower surface of the lower conductive elastic gasket 900 is open, except for a circular or polygonal edge portion 911 which contacts the bottom surface of the housing 100. That is, the lower conductive elastic gasket 900 has no element that can be referred to as a bottom surface except for the rim portion 911. However, in the present specification, as in the case of the upper conductive elastic gasket 600, a hypothetical lower surface will be assumed for convenience of explanation. It is preferable that the lower conductive elastic gasket 900 further includes an extended portion 913 extending from the circular or polygonal edge portion 911 in contact with the bottom surface of the housing 100 and extending horizontally or tilted upward Do. According to the extending portion 913, the contact between the bottom surface of the housing 100 and the rim portion 911 is more stably supported.

The lower conductive elastic gasket 900 also has a through hole 925 through which the dielectric resonator element fitting protrusion 110 provided at the bottom of the housing 100 passes through at the center and the dielectric resonator element 300 The inner region of the protrusion 921 protruded by forming the protrusion 921 on the circular or polygonal frame portion is formed as the dielectric resonator element mounting groove 923. The lower conductive elastic gasket 900 also has a structure in which the side surface is narrow in the upper part and inclined in the lower part in the wide shape.

When the lower conductive elastic gasket 900 is coupled with the dielectric resonator element 300, it is preferable that additional bonding by soldering is performed. That is, the coupling between the dielectric resonator element 300 and the lower conductive elastic gasket 900 preferably includes additional coupling by soldering. At this time, it is preferable that a conductor film formed by metallization is formed on the upper surface of the dielectric resonance element. The conductor film can be typically formed by silver (Ag).

10: dielectric resonator 100: housing
105: screw through hole 110: dielectric resonator element fitting protrusion
200: cover 205: screw through hole
210: outer cover 212: rim
214: inner cover seat groove 216: center hole
220: inner cover 300: dielectric resonator element
310: hollow 400: metal plate
410: dielectric resonator element top plate 412: rim protrusion
414: dielectric resonator element mounting groove 416:
420: central protrusion 422: screw through hole
500: metal plate fixing screw 600: upper conductive elastic gasket
611: upper surface frame portion 613:
621: lower edge projection 623: lower dielectric resonator element seat groove
625: Through hole 630: Side
700: Set screw 800: Tuning screw
810: Fixing nut 900: Lower conductive elastic gasket
911: lower edge portion 913: extension portion
921: upper surface rim protrusion 923: upper surface dielectric resonator element seating groove
925: through hole 930: side

Claims (16)

A housing having one side open and a receiving space therein; A cover covering an opening of the housing; A metal plate fixed to a bottom surface of the housing; A dielectric resonator element fixedly mounted on the metal plate and received in the housing space of the housing; And a conductive elastic gasket interposed between the dielectric and the lid and made of a metal material. The method according to claim 1,
Wherein the dielectric resonator element is formed in a cylindrical or polygonal cylindrical shape having a through hole in the center thereof. 3. The method of claim 2,
The metal plate may include a central protrusion formed on the upper portion of the circular or polygonal dielectric resonator element seating plate on which the dielectric resonator element is mounted and the central portion of the upper portion of the dielectric resonator element plate and sandwiching the through-hole hollow of the dielectric resonator element The dielectric resonator characterized by: The method of claim 3,
A rim protrusion is formed on a rim portion of the metal plate, and a region between the rim protruding portion and the center rim portion is formed by fitting a dielectric resonator element to the dielectric resonator element, Wherein the dielectric resonator is formed with a groove. The method according to any one of claims 3 and 4,
The metal plate has a structure in which the metal plate is in close contact with the bottom surface of the housing at the periphery of the bottom surface but is not in close contact with the bottom surface of the housing at the center of the bottom surface thereof, A dielectric resonator. 6. The method according to any one of claims 3 to 5,
Wherein the upper surface of the resonator element plate of the metal plate and the central protrusion portion are provided with screw through holes through which screws are passed in order and a screw through hole is also formed in the bottom surface of the housing, And the metal plate is fixed to the bottom surface of the housing by a screw being coupled to the through hole. The method according to claim 6,
Wherein the dielectric resonator element and the metal plate are further coupled by soldering. 8. The method according to any one of claims 1 to 7,
The conductive elastic gasket has a structure in which an upper surface thereof is an open shape except for a circular or polygonal edge portion that contacts the lid. The lower surface of the conductive elastic gasket has protrusions formed on a circular or polygonal rim, Wherein the inner region of the protrusion is formed of a dielectric resonator element mounting groove, and the side surface of the dielectric resonator has a wide upper portion and a narrower lower portion. 9. The method of claim 8,
Wherein the conductive elastic gasket further comprises an extended portion extending from a circular or polygonal rim portion in contact with the lid and extending horizontally or inclined downward. 10. A method according to any one of claims 8 and 9,
Wherein the conductive elastic gasket is made of an alloy of beryllium and copper. 11. The method according to any one of claims 1 to 10,
Wherein the lid includes an outer lid and an inner lid, the outer lid has a rim portion covering the rim of the opening of the housing, and an inner lid seating groove portion in which the inner lid is seated is formed in the rim portion, Wherein a central hole is formed at the center of the inner lid seat recess to allow the conductive elastic gasket to pass therethrough and the inner lid is engaged with the inner lid seat recess of the outer lid. A housing having one side opened, a dielectric resonator element fitting protrusion formed on a bottom surface thereof, and a receiving space therein; A cover covering an opening of the housing; A lower conductive elastic gasket formed of a metal material and fitted to the dielectric resonator element fitting protrusion formed on the bottom surface of the housing and closely contacting the bottom surface of the housing; The housing having a cylindrical or polygonal cylindrical shape having a through hole in the center thereof and being fitted in the dielectric resonator element fitting protrusion formed on the bottom surface of the housing and fixed on the lower conductive elastic gasket, A dielectric resonator element; And a top conductive elastic gasket interposed between the dielectric and the lid and made of a metal material. 13. The method of claim 12,
The upper conductive elastic gasket has a structure in which an upper surface thereof is formed in an open shape except for a circular or polygonal rim portion which contacts the lid and a lower surface is a place where the dielectric resonator element is seated and protrusions are formed on a circular or polygonal rim portion, The inner region of the protrusion is formed by the dielectric resonator element mounting groove, and the side surface is formed to have a wide upper portion and a narrower lower portion.
The lower conductive elastic gasket has a bottom surface that is open in shape except for a circular or polygonal edge portion that is in contact with the bottom surface of the housing. The top surface of the bottom conductive elastic gasket has a penetration hole, through which the dielectric resonator element fitting protrusion provided on the bottom surface of the housing passes, Wherein the upper surface of the dielectric resonator element is also a structure in which a protrusion is formed in a circular or polygonal rim portion so that an inner region of the protrusion is formed by a dielectric resonator element mounting groove, And the lower part of the dielectric resonator has a shape having a wide inclined shape. 14. The method of claim 13,
Wherein the upper conductive elastic gasket further comprises an extended portion extending from a circular or polygonal rim portion contacting with the lid and extending horizontally or inclined downward,
And a lower portion of the lower conductive elastic gasket is further provided with an extended portion that extends from a circular or polygonal rim portion contacting the bottom surface of the housing and extends horizontally or downwardly. 15. The method according to any one of claims 13 to 14,
Wherein the upper and lower conductive elastic gaskets are made of an alloy of beryllium and copper. 16. The method according to any one of claims 13 to 15,
Wherein the lid includes an outer lid and an inner lid, the outer lid has a rim portion covering the rim of the opening of the housing, and an inner lid seating groove portion in which the inner lid is seated is formed in the rim portion, Wherein a center hole is formed at the center of the inner lid seat recess to allow the upper conductive elastic gasket to pass therethrough and the inner lid is engaged with the inner lid seat recess of the outer lid.

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